This work reports development of yttrium doped copper oxide (Y-CuO) as a new hole transport material with supplemented optoelectronic character. The pure and Y-doped CuO thin films are developed through a solid-state method at 200 °C and recognized as high performance p-channel inorganic thin-film transistors (TFTs). CuO is formed by oxidative decomposition of copper acetylacetonate, yielding 100 nm thick and conductive (40.9 S cm-1 ) compact films with a band gap of 2.47 eV and charge carrier density of ∼1.44×1019 cm-3 . Yttrium doping generates denser films, Cu2 Y2 O5 phase in the lattice, with a wide band gap of 2.63 eV. The electrical conductivity increases nine-fold on 2 % Y addition to CuO, and the carrier density increases to 2.97×1021 cm-3 , the highest reported so far. The TFT devices perform remarkably with high field-effect mobility (μsat ) of 3.45 cm2 V-1 s-1 and 5.3 cm2 V-1 s-1 , and considerably high current-on/off ratios of 0.11×104 and 9.21×104 , for CuO and Y-CuO films, respectively (at -1 V operating voltage). A very small width hysteresis, 0.01 V for CuO and 1.92 V for 1 % Y-CuO, depict good bias stability. Both the devices work in enhancement mode with stable output characteristics for multiple forward sweeps (5 to -60 V) at -1Vg .
Keywords: copper oxide; doping; thin films; transistor; yttrium..
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